Parameter-Independent Strategies for pMDPs via POMDPs

Arming, Sebastian; Bartocci, Ezio; Chatterjee, Krishnendu; Katoen, Joost-Pieter; Sokolova, Ana

doi:10.1007/978-3-319-99154-2_4

Record link:

http://hdl.handle.net/20.500.12708/57507

Title:

Parameter-Independent Strategies for pMDPs via POMDPs

Citation:

Arming, S., Bartocci, E., Chatterjee, K., Katoen, J.-P., & Sokolova, A. (2018). Parameter-Independent Strategies for pMDPs via POMDPs. In A. McIver & A. Horvath (Eds.), Quantitative Evaluation of Systems: 15th International Conference, QEST 2018 (pp. 53–70). Springer. https://doi.org/10.1007/978-3-319-99154-2_4

Publisher DOI:

10.1007/978-3-319-99154-2_4

Publication Type:

Inproceedings - Poster Contribution

Authors:

Arming, Sebastian
Bartocci, Ezio
Chatterjee, Krishnendu
Katoen, Joost-Pieter
Sokolova, Ana

Organisational Unit:

E191-01 - Forschungsbereich Cyber-Physical Systems
E192-02 - Forschungsbereich Databases and Artificial Intelligence

Published in:

Quantitative Evaluation of Systems: 15th International Conference, QEST 2018

ISBN:

978-3-319-99153-5

Volume:

11024

DOI of the book:

10.1007/978-3-319-99154-2

Date (published):

2018

Event name:

Proc. of QEST 2018: the 15th International Conference on Quantitative Evaluation of Systems

Event date:

4-Sep-2018 - 7-Sep-2018

Event place:

Beijing, China, Non-EU

Number of Pages:

Publisher:

Springer, Cham

Peer reviewed:

Yes

Abstract:

Markov Decision Processes (MDPs) are a popular class of models suitable for solving control decision problems in probabilistic reactive systems. We consider parametric MDPs (pMDPs) that include parameters in some of the transition probabilities to account for stochastic uncertainties of the environment such as noise or input disturbances. We study pMDPs with reachability objectives where the parameter values are unknown and impossible to measure directly during execution, but there is a probability distribution known over the parameter values. We study for the first time computing parameter-independent strategies that are expectation optimal, i.e., optimize the expected reachability probability under the probability distribution over the parameters. We present an encoding of our problem to partially observable MDPs (POMDPs), i.e., a reduction of our problem to computing optimal strategies in POMDPs. We evaluate our method experimentally on several benchmarks: a motivating (repeated) learner model; a series of benchmarks of varying configurations of a robot moving on a grid; and a consensus protocol.

Research Areas:

Logic and Computation: 50%
Computer Engineering and Software-Intensive Systems: 50%

Science Branch:

Informatik

Appears in Collections:

Conference Paper

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